Elevation-Dependent Removal of Cirrus Clouds in Satellite Imagery

Masking of cirrus clouds in optical satellite imagery is an important step in automated processing chains. Firstly, it is a prerequisite to a subsequent removal of cirrus effects, and secondly, it affects the atmospheric correction, i.e., aerosol and surface reflectance retrievals. Cirrus clouds can be detected with a narrow bandwidth channel near 1.38 μ m and operational detection algorithms have been developed for Landsat-8 and Sentinel-2 images. However, concerning cirrus removal in the case of elevated surfaces, current methods do not separate the ground reflected signal from the cirrus signal in the 1.38 μ m channel when performing an atmospheric correction, often resulting in an overcorrection of the cirrus influence. We propose a new operational algorithm using a Digital Elevation Model (DEM) to estimate the surface and cirrus cloud contributions in the 1.38 μ m channel and to remove cirrus effects during the surface reflectance retrieval. Due to the highly variable nature of cirrus clouds and terrain conditions, no generic quantitative results could be derived. However, results for typical cases and the achieved improvement in cirrus removal are given for selected scenes and critical issues and limitations of the approach are discussed.

[1]  C. Woodcock,et al.  Improvement and expansion of the Fmask algorithm: cloud, cloud shadow, and snow detection for Landsats 4–7, 8, and Sentinel 2 images , 2015 .

[2]  A. Goetz,et al.  Cirrus cloud detection from airborne imaging spectrometer data using the 1 , 1993 .

[3]  Daniel Schläpfer,et al.  Combined Haze and Cirrus Removal for Multispectral Imagery , 2016, IEEE Geoscience and Remote Sensing Letters.

[4]  Y. Kaufman,et al.  Corection of thin cirrus path radiances in the 0.4–1.0 μm spectral region using the sensitive 1.375 μm cirrus detecting channel , 1998 .

[5]  E. Ben-Dor A precaution regarding cirrus cloud detection from airborne imaging spectrometer data using the 1.38 μm water vapor band , 1994 .

[6]  Andreas Uhl,et al.  Improvement of the Fmask algorithm for Sentinel-2 images: Separating clouds from bright surfaces based on parallax effects , 2018, Remote Sensing of Environment.

[7]  Daniel Schläpfer,et al.  Correction of cirrus effects in Sentinel-2 type of imagery , 2011 .

[8]  Daniel Schläpfer,et al.  An automatic atmospheric correction algorithm for visible/NIR imagery , 2006 .

[9]  Ping Yang,et al.  A new concept on remote sensing of cirrus optical depth and effective ice particle size using strong water vapor absorption channels near 1.38 and 1.88 /spl mu/m , 2004, IEEE Transactions on Geoscience and Remote Sensing.

[10]  Daniel Schläpfer,et al.  Operational Atmospheric Correction for Imaging Spectrometers Accounting for the Smile Effect , 2011, IEEE Transactions on Geoscience and Remote Sensing.

[11]  Stefan Adriaensen,et al.  Atmospheric Correction Inter-comparison eXercise , 2018, Remote. Sens..

[12]  M. Claverie,et al.  Preliminary analysis of the performance of the Landsat 8/OLI land surface reflectance product. , 2016, Remote sensing of environment.

[13]  Lawrence Ong,et al.  Landsat-8 Operational Land Imager Radiometric Calibration and Stability , 2014, Remote. Sens..

[14]  R. Richter,et al.  Correction of satellite imagery over mountainous terrain. , 1998, Applied optics.

[15]  Olivier Hagolle,et al.  Validation of Copernicus Sentinel-2 Cloud Masks Obtained from MAJA, Sen2Cor, and FMask Processors Using Reference Cloud Masks Generated with a Supervised Active Learning Procedure , 2019, Remote. Sens..

[16]  Zhe Zhu,et al.  Object-based cloud and cloud shadow detection in Landsat imagery , 2012 .

[17]  J. Roujean,et al.  An assessment of thin cloud detection by applying bidirectional reflectance distribution function model‐based background surface reflectance using Geostationary Ocean Color Imager (GOCI): A case study for South Korea , 2017 .

[18]  H. Chepfer,et al.  Cirrus Cloud Properties Derived from POLDER-1/ADEOS Polarized Radiances: First Validation Using a Ground-Based Lidar Network , 2000 .

[19]  Y. Kaufman,et al.  Selection of the 1.375-µm MODIS Channel for Remote Sensing of Cirrus Clouds and Stratospheric Aerosols from Space , 1995 .

[20]  D. C. Robertson,et al.  MODTRAN cloud and multiple scattering upgrades with application to AVIRIS , 1998 .

[21]  G. Thuillier,et al.  The Solar Spectral Irradiance from 200 to 2400 nm as Measured by the SOLSPEC Spectrometer from the Atlas and Eureca Missions , 2003 .

[22]  Bo-Cai Gao,et al.  Removal of Thin Cirrus Scattering Effects in Landsat 8 OLI Images Using the Cirrus Detecting Channel , 2017, Remote. Sens..

[23]  Matthias Drusch,et al.  Sentinel-2: ESA's Optical High-Resolution Mission for GMES Operational Services , 2012 .

[24]  David R. Thompson,et al.  Retrieval of Atmospheric Parameters and Surface Reflectance from Visible and Shortwave Infrared Imaging Spectroscopy Data , 2018, Surveys in Geophysics.